Heat of Compression Desiccant Air Dryers NRG-LES SERIES 350-10000 scfm (595-16990 nm 3 /h)
Where Ideas Meet Industry Since 1946, the world has turned to SPX FLOW s Pneumatic Products brand for the quality and service demanded by the most critical of applications. Global leaders of industry require durable components that deliver unquestionable reliability. Our precision engineered components and designs deliver outstanding service life and operational longevity. Invest in our experience and gain annuities that will grow for years. Based in Charlotte, North Carolina, SPX FLOW is a leading global supplier of highly engineered flow components, process equipment and turnkey systems, along with the related aftermarket parts and services, into the food and beverage, power and energy and industrial end markets. SPX FLOW has more than $2 billion in annual revenues and approximately 8,000 employees with operations in over 35 countries and sales in over 150 countries around the world. To learn more about SPX FLOW, please visit our website Pneumatic Products NRG-LES Series heat of compression desiccant air dryers provide a cost effective solution to remove moisture from compressed air. The sustainable energy saving design reduces operating costs and delivers instrument quality air. Thermal energy generated during the air compression process is effectively utilized to regenerate the off-line desiccant bed. Ideally suited for oil-free air compressors, NRG-LES Series dryers turn waste heat into energy savings. Advantages: Delivers ISO 8573.1: 2010 Air Quality Class 2 to 4 pressure dew point (-40ºF to +37ºF), dependent on air compressor discharge temperature Minimal power required, providing low cost of operation and rapid return on investment Desiccant in the off-line tower is regenerated without the use of purge air, requiring no increase in air compressor capacity Low outlet pressure dew points achieved without the use of blowers or booster heaters Fully packaged, skid mounted design, provides ease of installation Reduce Life Cycle Costs The NRG-LES consumes under 50 watts, less than the power requirement of a typical lap-top computer. The energy efficient design offers the lowest cost of operation as compared to conventional dehydration technology. Annual Cost of Operation at www.spxflow.com $18,000 $16,712 $16,000 $14,000 $12,000 $13,294 $11,568 $10,000 $8,000 $6,000 $4,904 $4,000 $2,000 $35 $0 Heatless Desiccant Heated Purge Desiccant Blower Purge Desiccant Non-Cycling Refrigerated Heat of Compression Desiccant Annual cost of operation based on: Air flow: 1000 scfm Cost of power: $0.10 kwh Operating time: 8000 hours
Better By Design Standard Features: Front View: Model NRG1025 Pressure vessels are designed in accordance with the ASME Boiler and Pressure Vessel Code Section VIII Division 1 ASME rated pressure relief valves control pressure build-up due to process upset Expanded metal personnel protection and hot pipe insulation provides added safety measures NEMA4/4X, IP66 rated controller, polycarbonate enclosure for protection in corrosive environments Flow models 350 to 450 scfm employ angle seat valves for reliable operation Flow models 600 to 10000 scfm utilize nonlubricated, high performance butterfly valves Front panel is equipped with left and right tower pressure gauges and moisture indicator for at a glance performance Towers are filled with high grade desiccant maintaining optimal performance under high temperatures 316 AISI stainless steel, brazed plate heat exchanger provides efficient cooling and corrosion resistance Fully insulated filter/separator removes bulk liquids and solid particles greater than 3.0 micron in size An electric demand drain serves as the primary drain, efficiently removing condensate without loss of air A timed electric drain acts as back-up, providing fail safe operation Factory mounted high temperature after-filter, rated for 450 F, removes solid particles 1.0 micron and larger Back View: Model NRG1025 Options: Tower insulation Moisture sensing dew point demand control with alarm Valve failure to shift alarm 3
Putting Waste Heat to Good Use How the NRG-LES Series Works: 1. Hot oil-free air, generated by the air compressor, is directed into the dryer by a high performance switching valve. 2. The hot air flows downward through the off-line tower, effectively regenerating the desiccant bed. 3. Hot, moist air then travels to the water-cooled heat exchanger. The cooling water runs counter-flow to the hot air causing water vapor in the air to condense. 4. Condensed liquid is removed in a high performance, two-stage filter/separator. Bulk liquid and solid particles 3.0 micron and larger are captured. 5. Condensate is discharged by an energy efficient, noair-loss demand drain. The system is equipped with a back-up drain providing fail safe operation. 6. The pre-cooled air flows upward through the on-line tower and is dried to the specified pressure dew point. 7. Air travels through a high temperature after-filter removing solid particles 1.0 micron and larger. Dry, oil-free air enters the system for use. 8. The cycle is reversed based on a one hour fixed time (30 minutes regenerating/30 minutes drying), or on an extended cycle. The cycle is extended based on the regenerating tower temperature or optional pressure dew point. 3 Water-Cooled Heat Exchanger 1 Hot Air Inlet 2 Regenerating Tower 8 Dry Air Outlet 7 After-filter 6 Drying Tower 4 Moisture Separator 5 Demand Drain
Understanding Dew Point Performance The Air Compression Process Site conditions are important when understanding dew point performance of heat of compression air dryers. The NRG-LES flow ratings are based on an ambient air temperature of 85ºF (29ºC) and 60% relative humidity. When compressed to 100 psig (7 bar) and heated to 350ºF (160ºC), the air leaving the compressor will possess a relative humidity of 3%. The dry, hot discharge air effectively regenerates the off-line desiccant bed. The Effect of Regeneration Temperature The NRG-LES utilizes recoverable heat energy from the air compressor to regenerate the off-line bed. Higher inlet air temperatures improve regeneration efficiency, delivering lower pressure dew points. Cooler inlet air temperatures decrease regeneration efficiency, delivering higher pressure dew points. Performance Basis: Operating Pressure: 100 psig (7 bar) Ambient Air Temperature: 85 F (29ºC) Ambient Relative Humidity: 60% Ambient Dew Point: 70ºF (21ºC) Pressure Dew Point Performance 50 40 230 F 30 Outlet Pressure Dew Point ( F) 20 10 0-10 -20-30 -40 3 2 260 F 290 F 320 F 350 F -50 1-60 55 60 65 70 75 80 85 90 95 100 105 Cooling Water Temperature ( F) The chart above demonstrates the effect of cooling water temperature & compressor discharge temperatures to pressure dew point. How to use the Dew Point Performance Chart: 1. Locate the cooling water temperature on the X-axis. Note: Inlet temperature to drying tower equals cooling water temperature plus 10ºF. 2. Proceed vertically up the graph line to where the cooling water temperature and compressor discharge temperature intersect. 3. From this coordinate, advance laterally across the graph line to the Y-axis to determine pressure dew point ( F). Example: 1. Cooling water temperature = 85ºF 2. Compressor discharge temperature = 350ºF 3. Resulting pressure dew point = -33ºF 5
Ease of Monitoring The NRG-LES controller is furnished with a comprehensive diagnostic system that provides real-time operating status, service due messages and fault conditions. Information is communicated in a highly visible, two (2) line sixteen (16) character vacuum florescent text display screen. The controller is equipped with an RS 232 communications port and Modbus registers for remote monitoring Status Text Display Screens Tower drying (left/right) Tower regenerating (left/right) Hours to service (filters/valves/desiccant) Inlet air temperature ( F/ C) Outlet air temperature ( F/ C) Left tower temperature ( F/ C) Right tower temperature ( F/ C) LT HEAT (1) RT DRYING Dryer Alarm Text Display Screens Demand drain failure Low inlet air temperature ( F/ C) High drying temperature (ºF/ºC) Service due (filters/valves/desiccant) Temperature sensor failure Optional: Outlet pressure dew point alarm (ºF/ºC) Valve position sensing- alarms on failure to shift Indicating Lights (LED) Tower status (drying/regenerating ) Power on (green) Master alarm light (red) Service due (amber) Panel Mounted Instrumentation Left and right tower pressure gauges Color change moisture indicator Optional Dew Point Demand Control System A dew point demand control system automatically extends the drying cycle to compensate for changes in operating conditions. By sampling exit air from the drying tower, the Demand Control System delays tower switchover until the moisture content at the sample port rises to the predetermined set point.
Product Specifications OPERATING CONDITIONS MINIMUM DESIGN MAXIMUM Regeneration Temperature 200 F Customer specific 450 F Inlet Air Pressure 60 psig 100 psig 150 psig Ambient Air Temperature 40 F 85 F 120 F Ambient Relative Humidity 60% Inlet Air Temperature (drying) 50 F 95 F 120 F Cooling Water Temperature 40 F 85 F 110 F DRYER MODEL RATED DIMENSIONS APPROXIMATE INLET/OUTLET COOLING FLOW WEIGHT CONNECTIONS WATER H W D (1) FLOW SCFM NM 3 /H IN MM IN MM IN MM LB KG IN GPM @ 85 F NRG350 350 560 96 2438 54 1372 43 1092 1794 814 2 x 3 NPT 8.7 NRG450 450 720 96 2438 56 1422 43 1092 1794 814 2 x 3 NPT 11.0 NRG600 600 960 105 2667 63 1600 50 1270 2294 1041 3 FLG x 3 NPT 15.0 NRG800 800 1280 105 2667 63 1600 50 1270 2518 1142 3 FLG x 3 NPT 20.0 NRG1025 1025 1640 108 2743 65 1651 48 1219 2818 1278 3 FLG x 3 NPT 26.0 NRG1300 1300 2080 115 2921 71 1803 62 1575 3438 1559 4 FLG 32.0 NRG1500 1500 2400 114 2896 77 1956 62 1575 4038 1832 4 FLG 37.0 NRG1800 1800 2880 119 3023 79 2007 62 1575 4538 2058 4 FLG 45.0 NRG2100 2100 3360 114 2896 87 2210 62 1575 5572 2527 4 FLG 52.0 NRG2400 2400 3840 116 2946 89 2261 67 1702 6472 2936 4 FLG 60.0 NRG3250 3250 5200 134 3404 99 2515 68 1727 7878 3573 6 FLG 81.0 NRG3700 3700 5920 126 3200 98 2489 85 2159 9638 4372 6 FLG 92.0 NRG4425 4425 7080 NRG5000 5000 8000 NRG6100 6100 9760 NRG7500 7500 12000 Consult Factory NRG8500 8500 13600 NRG10000 10000 16000 1 Flow ratings based on 100 psig operating pressure; 85 F cooling water; 95 F air temperature into drying tower. 2 Shipping weight includes factory mounted 1.0 micron after-filter. 7
NRG-LES Series 350 to 10000 scfm (595-16990 nm 3 /h) ISO Quality Classes Air Quality Classes ISO 8573-1: 2010 Solid Particles Water Oil Maximum number of particles per m 3 0.10-0.5 micron 0.5-1.0 micron 1.0-5.0 micron Vapor Pressure Dew Point Total Oil Concentration: Aerosol, Liquid and Vapor C F mg / m 3 ppm w/w 0 As specified by the equipment user or supplier and more stringent than class 1 1 O 20,000 O 400 O 10 O -70 O -94 0.01 0.008 2 O 400,000 O 6,000 O 100 O -40 O -40 0.1 0.08 3 - O 90,000 O 1,000 O -20 O -4 1 0.8 4 - - O 10,000 O +3 O +37 5 4 5 - - O 100,000 O +7 O +45 - - ISO Quality Class Performance: NRG-LES with After-Filter Class 2: Solids Class 2-4: Pressure Dew Point Correction Factors Flow Multiplier for Dryer Selection INLET TEMP TO DRYING TOWER * ºF (ºC) 85ºF 90ºF 95ºF 100ºF 105ºF 110ºF (29ºC) (32ºC) (35ºC) (38ºC) (41ºC) (43ºC) 60 (4) 1.2 1.4 1.7 2.0 2.3 2.8 70 (5) 1.0 1.2 1.4 1.7 2.0 2.4 80 (6) 0.9 1.1 1.3 1.5 1.7 2.1 90 (6) 0.9 1.1 1.3 1.6 1.8 Pressure psig (bar) 100 (7) 0.8 1.0 1.2 1.4 1.7 110 (8) 0.9 1.1 1.3 1.5 120 (8) 0.8 1.0 1.2 1.4 130 (9) 0.8 0.9 1.1 1.3 140 (10) 0.7 0.8 1.0 1.2 * Inlet temperature to drying tower = cooling water temperature +10ºF SPX FLOW INC. 4647 SW 40th Avenue Ocala, Florida 34474-5788 U.S.A. P: (352) 873-5793 F: (352) 873-5770 E: ppc.americas@spxflow.com www.spxflow.com/pneumatic-products SPX FLOW, Inc. reserves the right to incorporate our latest design and material changes without notice or obligation. Design features, materials of construction and dimensional data, as described in this bulletin, are provided for your information only and should not be relied upon unless confirmed in writing. Please contact your local sales representative for product availability in your region. For more information visit www.spxflow.com. The green and are trademarks of SPX FLOW, Inc. NRG-LES_NA Version: 02/2017 Issued: 07/2012 COPYRIGHT 2017 SPX FLOW INC.